Circuit Arrangement and Method for Transmitting Signals

1. A circuit arrangement for transmitting both single-ended logic-level-based data signals and clock signals, and differential, in particular common-mode-based, data signals and clock signals, in the form of at least one serialized common signal stream between at least one transmission arrangement assignable to at least one data source and at least one receiving arrangement assignable to at least one data sink, wherein the data rate of the differential data signals and clock signals is different from the data rate of the single-ended, logic-level-based data signals and clock signals, wherein the circuit arrangement comprises at least one serializer and at least one clock generator.

2. The circuit arrangement according to claim 1 , wherein the data rate of the differential data signals and clock signals is smaller than the data rate of the single-ended, logic-level-based data signals and clock signals.

3. The circuit arrangement according to claim 1 , wherein the transmission arrangement comprises: at least one input for the data signals and clock signals, at least one transmission interface logic downstream of the input for picking up the data signals and clock signals, the at least one serializer downstream of the transmission interface logic for generating the common signal stream, the at least one clock generator provided downstream of at least one clock module of the transmission interface logic, upstream of the serializer and for generating at least one reference clock, at least one output driver downstream of the serializer and at least one output downstream of the output driver for transmitting the common signal stream to the receiving arrangement.

4. The circuit arrangement according to claim 3 , wherein the clock generator is configured at least as a phase-locked-loop, in particular as an at least one clock multiplier unit.

5. The circuit arrangement according to claim 3 , wherein the serializer comprises: at least one framer downstream of the transmission interface logic for generating at least one frame recognizable in the receiving arrangement for the common signal stream as well as at least one multiplexer downstream of the framer for generating the common signal stream.

6. The circuit arrangement according to claim 5 , wherein both the single-ended, logic-level-based data signals and the differential data signals can be applied to the framer and in that the framer, by means of at least one coder, in particular by means of at least one 5b/6b coder block, embeds the differential data signals in the stream of the single-ended, logic-level-based data signals.

7. The circuit arrangement according to claim 5 , wherein the multiplexer comprises: at least one filter for differentiating between the differential data signals and/or clock signals, and the single-ended, logic-level-based data signals and/or clock signals, and at least one further multiplexer to which the differential data signals and/or clock signals coming from the filter can be additionally applied.

8. The circuit arrangement according to claim 1 , wherein the receiving arrangement comprises: at least one input for the common signal stream transmitted by the transmission arrangement, at least one input amplifier for picking up the common signal stream, at least one clock and data recovery unit for recovering the data signals and clock signals from the common signal stream, at least one clock module of at least one receiving interface logic downstream of the clock and data recovery unit, at least one deserializer downstream of the clock and data recovery unit for re-parallelizing the data and/or clock signals and for assigning the re-parallelized data and/or clock signals to the receiving interface logic and at least one output downstream of the receiving interface logic for the data signals and clock signals.

9. The circuit arrangement according to claim 8 , wherein the deserializer comprises: at least one demultiplexer downstream of the clock and data recovery unit for re-parallelizing the data and/or clock signals as well as at least one deframer downstream of the demultiplexer for assigning the re-parallelized data and/or clock signals to the receiving interface logic.

10. The circuit arrangement according to claim 9 , wherein the deframer separates the differential data signals by means of at least one decoder, in particular by means of at least one 6b/5b decoder block, from the single-ended, logic-level-based data signals and assigns the re-parallelized data signals to the respective data lines.

11. The circuit arrangement according to claim 1 , wherein the common signal stream is transferable between the transmission arrangement and the receiving arrangement via at least one optical medium, or via at least one electrical or galvanic.

12. A method for transmitting both single-ended logic-level-based data signals and clock signals, and differential, in particular common-mode-based, data and clock signals, in the form of at least one serialized common signal stream between at least one transmission arrangement assignable to at least one data source and at least one receiving arrangement assignable to at least one data sink, wherein the data rate of the differential data and clock signals is different from the data rate of the single-ended, logic-level-based data and clock signals.

13. The method according to claim 12 , wherein the data rate of the differential data and clock signals is smaller than the data rate of the single-ended, logic-level-based data and clock signals.

14. The method according to claim 12 , wherein the common signal stream between the transmission arrangement and the receiving arrangement is transmitted via at least one optical medium, or via at least one electrical or galvanic.